/*
- * Copyright (C) 1995-2007 University of Karlsruhe. All right reserved.
+ * Copyright (C) 1995-2008 University of Karlsruhe. All right reserved.
*
* This file is part of libFirm.
*
#undef IMAX
#define IMAX(a,b) ((a) > (b) ? (a) : (b))
-#define MAX_PROJ IMAX(pn_Load_max, pn_Store_max)
+#define MAX_PROJ IMAX(IMAX(pn_Load_max, pn_Store_max), pn_Call_max)
enum changes_t {
DF_CHANGED = 1, /**< data flow changed */
unsigned changes; /**< a bitmask of graph changes */
} walk_env_t;
-/**
- * flags for Load/Store
- */
-enum ldst_flags_t {
- LDST_VISITED = 1 /**< if set, this Load/Store is already visited */
-};
-
/** A Load/Store info. */
typedef struct _ldst_info_t {
ir_node *projs[MAX_PROJ]; /**< list of Proj's of this node */
ir_node *exc_block; /**< the exception block if available */
int exc_idx; /**< predecessor index in the exception block */
- unsigned flags; /**< flags */
unsigned visited; /**< visited counter for breaking loops */
} ldst_info_t;
*/
static void collect_nodes(ir_node *node, void *env)
{
- ir_op *op = get_irn_op(node);
+ ir_opcode opcode = get_irn_opcode(node);
ir_node *pred, *blk, *pred_blk;
ldst_info_t *ldst_info;
walk_env_t *wenv = env;
- if (op == op_Proj) {
- ir_node *adr;
- ir_op *op;
-
- pred = get_Proj_pred(node);
- op = get_irn_op(pred);
+ if (opcode == iro_Proj) {
+ pred = get_Proj_pred(node);
+ opcode = get_irn_opcode(pred);
- if (op == op_Load) {
+ if (opcode == iro_Load || opcode == iro_Store || opcode == iro_Call) {
ldst_info = get_ldst_info(pred, &wenv->obst);
wenv->changes |= update_projs(ldst_info, node);
- if ((ldst_info->flags & LDST_VISITED) == 0) {
- adr = get_Load_ptr(pred);
- ldst_info->flags |= LDST_VISITED;
- }
-
/*
* Place the Proj's to the same block as the
* predecessor Load. This is always ok and prevents
wenv->changes |= DF_CHANGED;
set_nodes_block(node, pred_blk);
}
- } else if (op == op_Store) {
- ldst_info = get_ldst_info(pred, &wenv->obst);
-
- wenv->changes |= update_projs(ldst_info, node);
-
- if ((ldst_info->flags & LDST_VISITED) == 0) {
- adr = get_Store_ptr(pred);
- ldst_info->flags |= LDST_VISITED;
- }
-
- /*
- * Place the Proj's to the same block as the
- * predecessor Store. This is always ok and prevents
- * "non-SSA" form after optimizations if the Proj
- * is in a wrong block.
- */
- blk = get_nodes_block(node);
- pred_blk = get_nodes_block(pred);
- if (blk != pred_blk) {
- wenv->changes |= DF_CHANGED;
- set_nodes_block(node, pred_blk);
- }
}
- } else if (op == op_Block) {
+ } else if (opcode == iro_Block) {
int i;
for (i = get_Block_n_cfgpreds(node) - 1; i >= 0; --i) {
else if (is_irn_forking(pred))
bl_info->flags |= BLOCK_HAS_COND;
- if (is_exc && (get_irn_op(pred) == op_Load || get_irn_op(pred) == op_Store)) {
+ opcode = get_irn_opcode(pred);
+ if (is_exc && (opcode == iro_Load || opcode == iro_Store || opcode == iro_Call)) {
ldst_info = get_ldst_info(pred, &wenv->obst);
wenv->changes |= update_exc(ldst_info, node, i);
static ir_entity *find_constant_entity(ir_node *ptr)
{
for (;;) {
- ir_op *op = get_irn_op(ptr);
-
- if (op == op_SymConst && (get_SymConst_kind(ptr) == symconst_addr_ent)) {
+ if (is_SymConst(ptr) && get_SymConst_kind(ptr) == symconst_addr_ent) {
ir_entity *ent = get_SymConst_entity(ptr);
if (variability_constant == get_entity_variability(ent))
return ent;
return NULL;
- } else if (op == op_Sel) {
+ } else if (is_Sel(ptr)) {
ir_entity *ent = get_Sel_entity(ptr);
ir_type *tp = get_entity_owner(ent);
/* try next */
ptr = get_Sel_ptr(ptr);
+ } else if (is_Add(ptr)) {
+ ir_node *l = get_Add_left(ptr);
+ ir_node *r = get_Add_right(ptr);
+
+ if (get_irn_mode(l) == get_irn_mode(ptr) && is_Const(r))
+ ptr = l;
+ else if (get_irn_mode(r) == get_irn_mode(ptr) && is_Const(l))
+ ptr = r;
+ else
+ return NULL;
+
+ /* for now, we support only one addition, reassoc should fold all others */
+ if (! is_SymConst(ptr) && !is_Sel(ptr))
+ return NULL;
+ } else if (is_Sub(ptr)) {
+ ir_node *l = get_Sub_left(ptr);
+ ir_node *r = get_Sub_right(ptr);
+
+ if (get_irn_mode(l) == get_irn_mode(ptr) && is_Const(r))
+ ptr = l;
+ else
+ return NULL;
+ /* for now, we support only one substraction, reassoc should fold all others */
+ if (! is_SymConst(ptr) && !is_Sel(ptr))
+ return NULL;
} else
return NULL;
}
*/
static compound_graph_path *rec_get_accessed_path(ir_node *ptr, int depth) {
compound_graph_path *res = NULL;
- ir_entity *root, *field;
- int path_len, pos;
+ ir_entity *root, *field, *ent;
+ int path_len, pos, idx;
+ tarval *tv;
+ ir_type *tp;
- if (get_irn_op(ptr) == op_SymConst) {
+ if (is_SymConst(ptr)) {
/* a SymConst. If the depth is 0, this is an access to a global
* entity and we don't need a component path, else we know
* at least it's length.
assert(get_SymConst_kind(ptr) == symconst_addr_ent);
root = get_SymConst_entity(ptr);
res = (depth == 0) ? NULL : new_compound_graph_path(get_entity_type(root), depth);
- } else {
- assert(get_irn_op(ptr) == op_Sel);
+ } else if (is_Sel(ptr)) {
/* it's a Sel, go up until we find the root */
res = rec_get_accessed_path(get_Sel_ptr(ptr), depth+1);
+ if (res == NULL)
+ return NULL;
/* fill up the step in the path at the current position */
field = get_Sel_entity(ptr);
assert(get_Sel_n_indexs(ptr) == 1 && "multi dim arrays not implemented");
set_compound_graph_path_array_index(res, pos, get_Sel_array_index_long(ptr, 0));
}
+ } else if (is_Add(ptr)) {
+ ir_node *l = get_Add_left(ptr);
+ ir_node *r = get_Add_right(ptr);
+ ir_mode *mode;
+
+ if (is_Const(r)) {
+ ptr = l;
+ tv = get_Const_tarval(r);
+ } else {
+ ptr = r;
+ tv = get_Const_tarval(l);
+ }
+ptr_arith:
+ mode = get_tarval_mode(tv);
+
+ /* ptr must be a Sel or a SymConst, this was checked in find_constant_entity() */
+ if (is_Sel(ptr)) {
+ field = get_Sel_entity(ptr);
+ } else {
+ field = get_SymConst_entity(ptr);
+ }
+ idx = 0;
+ for (ent = field;;) {
+ unsigned size;
+ tarval *sz, *tv_index, *tlower, *tupper;
+ long index;
+ ir_node *bound;
+
+ tp = get_entity_type(ent);
+ if (! is_Array_type(tp))
+ break;
+ ent = get_array_element_entity(tp);
+ size = get_type_size_bytes(get_entity_type(ent));
+ sz = new_tarval_from_long(size, mode);
+
+ tv_index = tarval_div(tv, sz);
+ tv = tarval_mod(tv, sz);
+
+ if (tv_index == tarval_bad || tv == tarval_bad)
+ return NULL;
+
+ assert(get_array_n_dimensions(tp) == 1 && "multiarrays not implemented");
+ bound = get_array_lower_bound(tp, 0);
+ tlower = computed_value(bound);
+ bound = get_array_upper_bound(tp, 0);
+ tupper = computed_value(bound);
+
+ if (tlower == tarval_bad || tupper == tarval_bad)
+ return NULL;
+
+ if (tarval_cmp(tv_index, tlower) & pn_Cmp_Lt)
+ return NULL;
+ if (tarval_cmp(tupper, tv_index) & pn_Cmp_Lt)
+ return NULL;
+
+ /* ok, bounds check finished */
+ index = get_tarval_long(tv_index);
+ ++idx;
+ }
+ if (! tarval_is_null(tv)) {
+ /* access to some struct/union member */
+ return NULL;
+ }
+
+ /* should be at least ONE array */
+ if (idx == 0)
+ return NULL;
+
+ res = rec_get_accessed_path(ptr, depth + idx);
+ if (res == NULL)
+ return NULL;
+
+ path_len = get_compound_graph_path_length(res);
+ pos = path_len - depth - idx;
+
+ for (ent = field;;) {
+ unsigned size;
+ tarval *sz, *tv_index;
+ long index;
+
+ tp = get_entity_type(ent);
+ if (! is_Array_type(tp))
+ break;
+ ent = get_array_element_entity(tp);
+ set_compound_graph_path_node(res, pos, ent);
+
+ size = get_type_size_bytes(get_entity_type(ent));
+ sz = new_tarval_from_long(size, mode);
+
+ tv_index = tarval_div(tv, sz);
+ tv = tarval_mod(tv, sz);
+
+ /* worked above, should work again */
+ assert(tv_index != tarval_bad && tv != tarval_bad);
+
+ /* bounds already checked above */
+ index = get_tarval_long(tv_index);
+ set_compound_graph_path_array_index(res, pos, index);
+ ++pos;
+ }
+ } else if (is_Sub(ptr)) {
+ ir_node *l = get_Sub_left(ptr);
+ ir_node *r = get_Sub_right(ptr);
+
+ ptr = l;
+ tv = get_Const_tarval(r);
+ tv = tarval_neg(tv);
+ goto ptr_arith;
}
return res;
} /* rec_get_accessed_path */
-/** Returns an access path or NULL. The access path is only
- * valid, if the graph is in phase_high and _no_ address computation is used.
+/**
+ * Returns an access path or NULL. The access path is only
+ * valid, if the graph is in phase_high and _no_ address computation is used.
*/
static compound_graph_path *get_accessed_path(ir_node *ptr) {
return rec_get_accessed_path(ptr, 0);
} /* get_accessed_path */
+typedef struct path_entry {
+ ir_entity *ent;
+ struct path_entry *next;
+ long index;
+} path_entry;
+
+static ir_node *rec_find_compound_ent_value(ir_node *ptr, path_entry *next) {
+ path_entry entry, *p;
+ ir_entity *ent, *field;
+ ir_initializer_t *initializer;
+ tarval *tv;
+ ir_type *tp;
+ unsigned n;
+
+ entry.next = next;
+ if (is_SymConst(ptr)) {
+ /* found the root */
+ ent = get_SymConst_entity(ptr);
+ initializer = get_entity_initializer(ent);
+ for (p = next; p != NULL;) {
+ if (initializer->kind != IR_INITIALIZER_COMPOUND)
+ return NULL;
+ n = get_initializer_compound_n_entries(initializer);
+ tp = get_entity_type(ent);
+
+ if (is_Array_type(tp)) {
+ ent = get_array_element_entity(tp);
+ if (ent != p->ent) {
+ /* a missing [0] */
+ if (0 >= n)
+ return NULL;
+ initializer = get_initializer_compound_value(initializer, 0);
+ continue;
+ }
+ }
+ if (p->index >= n)
+ return NULL;
+ initializer = get_initializer_compound_value(initializer, p->index);
+
+ ent = p->ent;
+ p = p->next;
+ }
+ tp = get_entity_type(ent);
+ while (is_Array_type(tp)) {
+ ent = get_array_element_entity(tp);
+ tp = get_entity_type(ent);
+ /* a missing [0] */
+ n = get_initializer_compound_n_entries(initializer);
+ if (0 >= n)
+ return NULL;
+ initializer = get_initializer_compound_value(initializer, 0);
+ }
+
+ switch (initializer->kind) {
+ case IR_INITIALIZER_CONST:
+ return get_initializer_const_value(initializer);
+ case IR_INITIALIZER_TARVAL:
+ case IR_INITIALIZER_NULL:
+ default:
+ return NULL;
+ }
+ } else if (is_Sel(ptr)) {
+ entry.ent = field = get_Sel_entity(ptr);
+ tp = get_entity_owner(field);
+ if (is_Array_type(tp)) {
+ assert(get_Sel_n_indexs(ptr) == 1 && "multi dim arrays not implemented");
+ entry.index = get_Sel_array_index_long(ptr, 0) - get_array_lower_bound_int(tp, 0);
+ } else {
+ int i, n_members = get_compound_n_members(tp);
+ for (i = 0; i < n_members; ++i) {
+ if (get_compound_member(tp, i) == field)
+ break;
+ }
+ if (i >= n_members) {
+ /* not found: should NOT happen */
+ return NULL;
+ }
+ entry.index = i;
+ }
+ return rec_find_compound_ent_value(get_Sel_ptr(ptr), &entry);
+ } else if (is_Add(ptr)) {
+ ir_node *l = get_Add_left(ptr);
+ ir_node *r = get_Add_right(ptr);
+ ir_mode *mode;
+ unsigned pos;
+
+ if (is_Const(r)) {
+ ptr = l;
+ tv = get_Const_tarval(r);
+ } else {
+ ptr = r;
+ tv = get_Const_tarval(l);
+ }
+ptr_arith:
+ mode = get_tarval_mode(tv);
+
+ /* ptr must be a Sel or a SymConst, this was checked in find_constant_entity() */
+ if (is_Sel(ptr)) {
+ field = get_Sel_entity(ptr);
+ } else {
+ field = get_SymConst_entity(ptr);
+ }
+
+ /* count needed entries */
+ pos = 0;
+ for (ent = field;;) {
+ tp = get_entity_type(ent);
+ if (! is_Array_type(tp))
+ break;
+ ent = get_array_element_entity(tp);
+ ++pos;
+ }
+ /* should be at least ONE entry */
+ if (pos == 0)
+ return NULL;
+
+ /* allocate the right number of entries */
+ NEW_ARR_A(path_entry, p, pos);
+
+ /* fill them up */
+ pos = 0;
+ for (ent = field;;) {
+ unsigned size;
+ tarval *sz, *tv_index, *tlower, *tupper;
+ long index;
+ ir_node *bound;
+
+ tp = get_entity_type(ent);
+ if (! is_Array_type(tp))
+ break;
+ ent = get_array_element_entity(tp);
+ p[pos].ent = ent;
+ p[pos].next = &p[pos + 1];
+
+ size = get_type_size_bytes(get_entity_type(ent));
+ sz = new_tarval_from_long(size, mode);
+
+ tv_index = tarval_div(tv, sz);
+ tv = tarval_mod(tv, sz);
+
+ if (tv_index == tarval_bad || tv == tarval_bad)
+ return NULL;
+
+ assert(get_array_n_dimensions(tp) == 1 && "multiarrays not implemented");
+ bound = get_array_lower_bound(tp, 0);
+ tlower = computed_value(bound);
+ bound = get_array_upper_bound(tp, 0);
+ tupper = computed_value(bound);
+
+ if (tlower == tarval_bad || tupper == tarval_bad)
+ return NULL;
+
+ if (tarval_cmp(tv_index, tlower) & pn_Cmp_Lt)
+ return NULL;
+ if (tarval_cmp(tupper, tv_index) & pn_Cmp_Lt)
+ return NULL;
+
+ /* ok, bounds check finished */
+ index = get_tarval_long(tv_index);
+ p[pos].index = index;
+ ++pos;
+ }
+ if (! tarval_is_null(tv)) {
+ /* hmm, wrong access */
+ return NULL;
+ }
+ p[pos - 1].next = next;
+ return rec_find_compound_ent_value(ptr, p);
+ } else if (is_Sub(ptr)) {
+ ir_node *l = get_Sub_left(ptr);
+ ir_node *r = get_Sub_right(ptr);
+
+ ptr = l;
+ tv = get_Const_tarval(r);
+ tv = tarval_neg(tv);
+ goto ptr_arith;
+ }
+ return NULL;
+}
+
+static ir_node *find_compound_ent_value(ir_node *ptr) {
+ return rec_find_compound_ent_value(ptr, NULL);
+}
+
/* forward */
static void reduce_adr_usage(ir_node *ptr);
exchange(info->projs[pn_Load_M], mem);
if (info->projs[pn_Load_X_regular])
exchange(info->projs[pn_Load_X_regular], new_r_Jmp(current_ir_graph, get_nodes_block(load)));
- exchange(load, new_Bad());
+ kill_node(load);
reduce_adr_usage(ptr);
}
} /* handle_load_update */
} /* can_use_stored_value */
/**
- * Follow the memory chain as long as there are only Loads
- * and alias free Stores and try to replace current Load or Store
- * by a previous ones.
+ * Check whether a Call is at least pure, ie. does only read memory.
+ */
+static unsigned is_Call_pure(ir_node *call) {
+ ir_type *call_tp = get_Call_type(call);
+ unsigned prop = get_method_additional_properties(call_tp);
+
+ /* check first the call type */
+ if ((prop & (mtp_property_const|mtp_property_pure)) == 0) {
+ /* try the called entity */
+ ir_node *ptr = get_Call_ptr(call);
+
+ if (is_Global(ptr)) {
+ ir_entity *ent = get_Global_entity(ptr);
+
+ prop = get_entity_additional_properties(ent);
+ }
+ }
+ return (prop & (mtp_property_const|mtp_property_pure)) != 0;
+} /* is_Call_pure */
+
+/**
+ * Follow the memory chain as long as there are only Loads,
+ * alias free Stores, and constant Calls and try to replace the
+ * current Load by a previous ones.
* Note that in unreachable loops it might happen that we reach
* load again, as well as we can fall into a cycle.
* We break such cycles using a special visited flag.
if (info->projs[pn_Load_res])
exchange(info->projs[pn_Load_res], value);
- exchange(load, new_Bad());
+ kill_node(load);
reduce_adr_usage(ptr);
return res | DF_CHANGED;
}
res |= CF_CHANGED;
}
- exchange(load, new_Bad());
+ kill_node(load);
reduce_adr_usage(ptr);
return res |= DF_CHANGED;
}
get_irn_mode(get_Store_value(pred)),
ptr, load_mode);
/* if the might be an alias, we cannot pass this Store */
- if (rel != no_alias)
+ if (rel != ir_no_alias)
break;
pred = skip_Proj(get_Store_mem(pred));
- } else if (get_irn_op(pred) == op_Load) {
+ } else if (is_Load(pred)) {
pred = skip_Proj(get_Load_mem(pred));
+ } else if (is_Call(pred)) {
+ if (is_Call_pure(pred)) {
+ /* The called graph is at least pure, so there are no Store's
+ in it. We can handle it like a Load and skip it. */
+ pred = skip_Proj(get_Call_mem(pred));
+ } else {
+ /* there might be Store's in the graph, stop here */
+ break;
+ }
} else {
/* follow only Load chains */
break;
for (i = get_Sync_n_preds(pred) - 1; i >= 0; --i) {
res |= follow_Mem_chain(load, skip_Proj(get_Sync_pred(pred, i)));
if (res)
- break;
+ return res;
}
}
exchange(info->projs[pn_Load_X_regular], new_r_Jmp(current_ir_graph, get_nodes_block(load)));
res |= CF_CHANGED;
}
- exchange(load, new_Bad());
+ kill_node(load);
reduce_adr_usage(ptr);
return res | DF_CHANGED;
}
if (info->projs[pn_Load_res])
exchange(info->projs[pn_Load_res], new_node);
- exchange(load, new_Bad());
+ kill_node(load);
reduce_adr_usage(ptr);
return res | DF_CHANGED;
}
res |= DF_CHANGED;
}
}
- exchange(load, new_Bad());
+ kill_node(load);
reduce_adr_usage(ptr);
return res;
} else {
- compound_graph_path *path = get_accessed_path(ptr);
-
- if (path) {
- ir_node *c;
-
- assert(is_proper_compound_graph_path(path, get_compound_graph_path_length(path)-1));
- /*
- {
- int j;
- for (j = 0; j < get_compound_graph_path_length(path); ++j) {
- ir_entity *node = get_compound_graph_path_node(path, j);
- fprintf(stdout, ".%s", get_entity_name(node));
- if (is_Array_type(get_entity_owner(node)))
- fprintf(stdout, "[%d]", get_compound_graph_path_array_index(path, j));
- }
- printf("\n");
- }
- */
-
- c = get_compound_ent_value_by_path(ent, path);
- free_compound_graph_path(path);
+ ir_node *c = NULL;
+ if (ent->has_initializer) {
+ /* new style initializer */
+ c = find_compound_ent_value(ptr);
+ } else {
+ /* old style initializer */
+ compound_graph_path *path = get_accessed_path(ptr);
- /* printf(" cons: "); DDMN(c); */
+ if (path) {
+ assert(is_proper_compound_graph_path(path, get_compound_graph_path_length(path)-1));
+ c = get_compound_ent_value_by_path(ent, path);
+ free_compound_graph_path(path);
+ }
+ }
+ if (c != NULL) {
if (info->projs[pn_Load_M]) {
exchange(info->projs[pn_Load_M], mem);
res |= DF_CHANGED;
exchange(info->projs[pn_Load_res], copy_const_value(get_irn_dbg_info(load), c));
res |= DF_CHANGED;
}
- exchange(load, new_Bad());
+ kill_node(load);
reduce_adr_usage(ptr);
return res;
} else {
Reflectiontest.
printf(">>>>>>>>>>>>> Found access to constant entity %s in function %s\n", get_entity_name(ent),
get_entity_name(get_irg_entity(current_ir_graph)));
- printf(" load: "); DDMN(load);
- printf(" ptr: "); DDMN(ptr);
+ ir_printf(" load: %+F\n", load);
+ ir_printf(" ptr: %+F\n", ptr);
*/
}
}
get_nodes_MacroBlock(pred) == mblk &&
is_completely_overwritten(get_irn_mode(get_Store_value(pred)), mode)) {
/*
- * a Store after a Store in the same block -- a write after write.
+ * a Store after a Store in the same MacroBlock -- a write after write.
* We may remove the first Store, if it does not have an exception handler.
*
* TODO: What, if both have the same exception handler ???
if (get_Store_volatility(pred) != volatility_is_volatile && !pred_info->projs[pn_Store_X_except]) {
DBG_OPT_WAW(pred, store);
exchange(pred_info->projs[pn_Store_M], get_Store_mem(pred));
- exchange(pred, new_Bad());
+ kill_node(pred);
reduce_adr_usage(ptr);
return DF_CHANGED;
}
} else if (is_Load(pred) && get_Load_ptr(pred) == ptr &&
value == pred_info->projs[pn_Load_res]) {
/*
- * a Store of a value after a Load -- a write after read.
- * We may remove the second Store, if it does not have an exception handler.
+ * a Store of a value just loaded from the same address
+ * -- a write after read.
+ * We may remove the Store, if it does not have an exception
+ * handler.
*/
if (! info->projs[pn_Store_X_except]) {
DBG_OPT_WAR(store, pred);
exchange(info->projs[pn_Store_M], mem);
- exchange(store, new_Bad());
+ kill_node(store);
reduce_adr_usage(ptr);
return DF_CHANGED;
}
get_irn_mode(get_Store_value(pred)),
ptr, mode);
/* if the might be an alias, we cannot pass this Store */
- if (rel != no_alias)
+ if (rel != ir_no_alias)
break;
pred = skip_Proj(get_Store_mem(pred));
- } else if (get_irn_op(pred) == op_Load) {
+ } else if (is_Load(pred)) {
+ ir_alias_relation rel = get_alias_relation(
+ current_ir_graph, get_Load_ptr(pred), get_Load_mode(pred),
+ ptr, mode);
+ if (rel != ir_no_alias)
+ break;
+
pred = skip_Proj(get_Load_mem(pred));
} else {
/* follow only Load chains */
/* follow the memory chain as long as there are only Loads */
INC_MASTER();
+
return follow_Mem_chain_for_Store(store, skip_Proj(mem));
} /* optimize_store */
store = skip_Proj(projM);
old_store = store;
- if (get_irn_op(store) != op_Store)
+ if (!is_Store(store))
return 0;
block = get_nodes_block(store);
case iro_Phi:
wenv->changes |= optimize_phi(n, wenv);
+ break;
default:
;
};
/**
- * Move loops out of loops if possible
+ * Move loops out of loops if possible.
+ *
+ * @param pscc the loop described by an SCC
+ * @param env the loop environment
*/
-static void move_loads_in_loops(scc *pscc, loop_env *env) {
+static void move_loads_out_of_loops(scc *pscc, loop_env *env) {
ir_node *phi, *load, *next, *other, *next_other;
ir_entity *ent;
int j;
if (info->projs[pn_Load_res] == NULL || info->projs[pn_Load_X_regular] != NULL || info->projs[pn_Load_X_except] != NULL)
continue;
- /* for now, we can only handle Load(SymConst) */
- if (! is_SymConst(ptr) || get_SymConst_kind(ptr) != symconst_addr_ent)
+ /* for now, we can only handle Load(Global) */
+ if (! is_Global(ptr))
continue;
- ent = get_SymConst_entity(ptr);
+ ent = get_Global_entity(ptr);
load_mode = get_Load_mode(load);
for (other = pscc->head; other != NULL; other = next_other) {
node_entry *ne = get_irn_ne(other, env);
get_irn_mode(get_Store_value(other)),
ptr, load_mode);
/* if the might be an alias, we cannot pass this Store */
- if (rel != no_alias)
+ if (rel != ir_no_alias)
break;
}
+ /* only pure Calls are allowed here, so ignore them */
}
if (other == NULL) {
ldst_info_t *ninfo;
}
}
}
-} /* move_loads_in_loops */
+} /* move_loads_out_of_loops */
/**
* Process a loop SCC.
next = e->next;
switch (get_irn_opcode(irn)) {
case iro_Call:
+ if (is_Call_pure(irn)) {
+ /* pure calls can be treated like loads */
+ only_phi = 0;
+ break;
+ }
+ /* non-pure calls must be handle like may-alias Stores */
+ goto fail;
case iro_CopyB:
- /* cannot handle Calls or CopyB yet */
+ /* cannot handle CopyB yet */
goto fail;
case iro_Load:
process = 1;
}
DB((dbg, LEVEL_2, "\n"));
- move_loads_in_loops(pscc, env);
+ move_loads_out_of_loops(pscc, env);
fail:
;
for (i = get_Block_n_cfgpreds(endblk) - 1; i >= 0; --i) {
ir_node *pred = get_Block_cfgpred(endblk, i);
+ pred = skip_Proj(pred);
if (is_Return(pred))
dfs(get_Return_mem(pred), env);
else if (is_Raise(pred))
/**
* Initialize new phase data. We do this always explicit, so return NULL here
*/
-static void *init_loop_data(ir_phase *ph, ir_node *irn, void *data) {
+static void *init_loop_data(ir_phase *ph, const ir_node *irn, void *data) {
(void)ph;
(void)irn;
(void)data;
assert(get_irg_pinned(irg) != op_pin_state_floats &&
"LoadStore optimization needs pinned graph");
- if (! get_opt_redundant_loadstore())
- return;
-
/* we need landing pads */
remove_critical_cf_edges(irg);